Brake control means



Sept. 16, 1941.

E. G. ERSON BRAKE CONTROL MEANS Filed April 26, 1940 2 Sheets-Sheet l INVENTOR ERIK G. ERSON 1/6771? ATTORNEY Patented Sept. 16, 1941 Units!) s'r'rss BRAKE CONTROL MEANS Erik G. Erson, Wilkinsburg, Pa., assignor to The Westinghouse Air Brake Company, Wilmerding, Pa., a corporation of Pennsylvania This invention relates to locomotive brake equipment and more particularly to the type embodying means operable by the engineer to control the brakes on the locomotive and cars of a train, and operable also by means responsive to a change in track signals, in case of unfavorable trafiic conditions, for automatically applylng the brakes on the locomotive and cars of the tra n. In the copending application of Ellis E. Hew1tt and Donald L. McNeal, Serial No. 326,352, filed March 28, 1940, there is disclosed a brake equipment of the above type which is operative either by the engineer or in response to a change In track signals for controlling the brakes on the locomotive and train through the medium of either a brake pipe, involving the usual automatic principle, or a straight air tram pipe, involving the usual straight air principle.

TheHewitt and McNeal brake equipment embodies an engineers brake valve device having an automatic portion for controlling the brakes automatically through the brake pipe and a straight air portion for controlling the brakes by straight air through the straight air pipe. A selector handle on the side of the brake valve device is movable to an automatic posltion for rendering the automatic portion operative and to a straight air position for rendering the straight air portion operative. The equipment further comprises a brake application valve device which is adapted to operate automatically upon an adverse change in track signals to apply the brakes on the locomotive and cars of the train through the medium of either the brake pipe or straight air pipe.

Also associated with the brake equipment is an. automatic suppression device and a straight air suppression device, either one or the other of which is adapted to operate to prevent response of the brake application valve device to a change,

in track signals if the engineer is alert and operates the brake valve device to initiate an application or the brakes on the locomotive and train promptly when warned of such change. The automatic suppression device is operative upon operation of the brake valve device when the selector handle is in the automatic position, while the straight air supression device is operative upon operation of the brake valve device when the selector handle is in the straight air position.

The straight air suppression device is controlled by straight air pipe pressure and in order to insure the prompt operation thereof, upon initiating a straight air application of the brakes orrics by the brake valve device, so as toprevent response of the brake application valve device to a change in track signals, the fluid for operating said suppression device is taken from a communication ahead of a choke through which the fluid pressure is adapted to be supplied to the straight air pipe for effecting the straight air application of brakes. By this arrangement the fluid pressure for operating the straight air suppression device builds up ahead of that'in the straight air pipe to provide prompt suppression operation of said device, whereas if the suppression device were connected directly to the straight air pipe and the pressure for operating same therefore increased with straight air pipe pressure, the suppression device Would not be operated until the straight air pipe pressure had been increased to a degree which would provide substantially a full straight air application of brakes.

With the choke arrangement however it will be noted that in casethe supply of fluid ahead of the choke is limited or cut off by the brake valve device before the pressure in the straight air pipe is increased to a degree which would in-- sure the straight air suppression device remaining in the suppression position, thepressure holding th suppression device in the suppression position will equalize through the choke into the straight air pipe and the suppression device will then move out of its suppression position and permit operation of the brake application valve device to efiect an automatic application of the brakes on the locomotive and train. In other words, in order that the straight air suppression device will remain in its suppressing position to maintain the brake application Valve suppressed, it is necessary that the engineer provide a continuous increase in pressure in the straight air pipe to the degree required for operating the independent'suppression device.

On certain railroads employing this type of brake equipment an electropneumatic straight air application of brakes on the locomotive and cars of a train is at times effected in two stages or steps with a time interval between the steps;

that is, the engineer will operate thebrake valve' device will prevent operation of the brake application valve device only during the initial step of increase in pressure in the straight air pipe, since during the interval of time between the two steps the pressure on the suppression device will reduce into the straight air pipe to such a degree that the suppression device will operate to cause the brake application valve device to respond to the unfavorable track signal, which is undesired.

The straight air suppression device above described was not intended to provide permanent suppression of the brake application valve device upon a change in track signals when the straight air pipe pressure was increased in steps as just described, rather it was designed to provide permanent suppression of the application valve device only when a straight air application of brakes is efiected in a single and continuous step up to the degree required for holding the device in its suppressing position.

The principal object of the invention is therefore to provide a straight air suppression device which is adapted to operate to suppress the operation of the application valve device when the brake valve device is operated to effect a straight air application of brakes on the locomotive and cars of a train in either a single continuous step Y or in two steps with an intervening lapse of time, as above described.

Other objects and advantages will be apparent from the following more detailed description of the invention.

In the accompanying drawings; Fig. 1 is a diagrammatic view, partly in section and partly in outline, of a portion of a locomotive brake equipment embodying the invention; and Fig. 2 is a diagrammatic sectional view of a modification of the invention.

Description of parts in Fig. 1

The straight air suppression valve device embodying the present invention is adapted to be associated with a locomotive brake equipment of the type disclosed in the aforementioned pending application, however, only those parts are shown in the drawing of the present application which are deemed essential to a clear understanding of the invention.

Th brake equipment shown in the drawing comprises an engineers brake valve device I, a

master switch device 2, an application and release magnet valve device 3, a brake application valve device 4, a-timing device 5, a double check valve device 6, a main reservoir 1, and two feed valve devices 8 and 9. Associated with the brake application valve device 4 and removably secured thereto is a straight air suppression valve device l0, constructed in accordance with the present invention.

The engineers brake valve device I comprises a self-lapping brake application and release valve portion H adapted to be controlled by movement of a handle l2 in an application and release zone for varying the fluid pressure in a straight air control pipe I3 in accordance with the position of said handle in said zone. Movement of handle E2 in one direction is adapted to increase the pressure in pipe 13 in accordance with the degree of brake application desired on the locomotive and cars of a train, while movement of the handle in the opposite direction is adapted to reduce the pressure in said pipe for releasing the brakes on the locomotive and cars of the train. Fluid under pressure for supply by the valve portion ll of the brake valve device to pipe I3 is obtained from the main reservoir I through the feed valve device 9 and feed valve pipe M. A further description of these parts of the engineers brake valve device is not deemed essential to a clear understanding of .the present invention.

The engineers brake valve device I further comprises a poppet valve I5 contained in a chamber it which is connected by passage and pipe H to the brake application valve device 4. The valve I5 is provided for controlling communication between chamber 16 and a vent port l8 which leads to the atmosphere. A spring l9 in chamber i6 acts on valve l5 for urging it to its seat. The valve !5 has a stem 20 extending through a bore in the casing for engagement by a cam 2! provided on a sleeve 22 which is secured to a shaft 23 connected to the handle l2 for rotation thereby and through the medium of which the self-lapping valve portion ll of the brake valve device is controlled. In the usual release position of the brake valve handle 12, in which it is shown, the cam 2| is adapted to unseat the valve I5, while upon movement of the handle out of the release position to supply fluid under pressure to the straight air control pipe E3 to eifect a straight air application of the brakes on the locomotive and cars of the train the cam 2! is operative to permit spring IE to move the valve Hi to its seated position.

The master switch device 2 comprise a casing containing two flexible diaphragms 21 and 28 arranged in spaced relation and connected by a stem 29 for movement together. The diaphragm 27 has at its outer face a chamber 30 which is connected by a pipe 3| to the side outlet of the double check valve device 6. At the opposite face of diaphragm 28 there is provided a chamber 32 which is in permanent communication with a straight air train pipe 33 through which the brakes on the locomotive and cars of a train are adapted to be controlled on the usual straight air principle. Intermediate the diaphragms 21 and 23 there is a chamber 34 which contains a movable contact 35 secured to but properly insulated from the stem 29 and movable with said stem upon deflection of the diaphragms 21 and 28. The contact 35 is connected by a suitable conductor 36 to any desired source of electric current such as to one terminal of a battery 31 the other terminal of which is grounded. Carried by the casing and extending into chamber 34 for engagement by the contact 35 are a pair of contact fingers 38 and 39, said fingers being so arranged that upon movement of contact 35 in the direction of the right hand said contact will engage first the finger 38 and then the finger 39, while upon movement of contact 35 in the reverse direction said fingers will be disconnected therefrom in the reverse order. The finger 38 is connected to a. release train wire 40 while the finger 39 is connected to an application train wire 4!.

The application and release magnet valve device 3 comprises an application magnet valve portion 42 connected to the application train wire ll and a release magnet valve portion 43 connected to the release train wire 40. Energization of the application magnet valve portion 42 upon supply of electric current to the app ication train wire t! is adapted to supply fluid under pressure from the feed valve pipe 14 to the straight air pipe 33 for effecting a straight air application .of brakes, while deenergization of said portion is adapted to cut off the supply of fluid under pressure to the straight air pipe for limiting the degree of a brake application or for permitting a release of brakes. The release mag net valve portion 43 is normally deenergized to Permit the ventingof fluid under pressure from the straight air pipe 33 for effecting the release of a straight air application of brakes and is operative upon energization to close the vent from the straight air pipe 33 so that the brakes may be applied in accordance with the operation of the application magnet valve portion 42.

The brake application valve device 4 comprises a casing containing a piston 45 and a slide valve 45 connected to said piston for movement therewith. The slide valve 46 is contained in a chamber 4! at one side of the piston 45 and said chamber is connected to the feed valve pipe I4 and is at all times charged with fluid under pressure supplied by the feed valve device 9. At the opposite side of the piston 45 there is a chamber 48 connected to a control pipe 49 and containing a spring 50 acting on the piston for urging the same and the slide valve 45 to their normal position shown.

The timing valve device comprises a double beat valve 52 contained in a chamber 53 which is connected by passages and pipe 54 to the straight air suppression valve device I9. The double beat valve 52 is provided for controlling communication between chamber 53 and a chamber 55 above the valve and a chamber 56 below the valve, said valve having oppositely disposed fluted stems 57 and 58 extending through suitable bores in the casing into the chambers 55 and 56, respectively.

The chamber 55 is in permanent communication through pipe 49 with the application piston chamber 48 and contains a spring 59 acting on the fluted stem 51 for urging the double beat valve 52 to its lower seated position. The cham-' ber 55 is formed at theupper face on a valve piston SI which is slidably mounted in the casing, said chamber being open to the atmosphere through a port 52 and containing a spring 63 acting on said valve piston for urging it to its lower position.

Interposed between the valve piston SI and the fluted stem 551s a spring 65 which is operative when said valve piston is in the position shown to hold the double beat valve 52 in its upper seated position. At the lower face of the valve piston SI there is a chamber 65 in communication with a volume reservoir 51.

An electromagnet I9 is provided which is adapted to be controlled by mechanism (not shown) responsive to changes in track signal circuits in such a manner that when the track signals are favorable the magnet 75 will be energized and when unfavorable, requiring that the train'be slowed down or stopped, deenergized.

The electromagnet I9 is arranged to control two oppositely seating coaxially arranged poppet valves II and 12. The valve H is contained in a chamber 73 which is open to the atmosphere through a restricted vent port M as well as by way of a signal whistle l5 and said valve is a1'- ranged to control communication between said chamber and a chamber 16 which is open to the volume reservoir 61 through a communication including a restricted portion or choke TI and a check valve IS, the check valve I8 being provided to allow rapid flow of fluid under pressure in the direction of reservoir 61, while the restricted portion TI is adapted to restrict the flow of fluid from reservoir-61 to the chamber I6.

The valve I2 is contained in a chamber which is constantly supplied with fluid at a desired reduced pressure from the feed valvedevice 8 through a pipe'BI. A spring 82in chamber 89 acts on the valve I2 for urging it in the direction of its seat.v The valve 12 isprovided dition fluid under pressure supplied by the feed valve 8 to valve chamber 80 is adapted to flow to chamber 16 and thenpast the check valve I8 to the reservoir 51 and chamber 56 below the valve piston SI to act on said valve piston for holding same and thereby the double beat valve 52 in their upper'positions, as shown. Upon deenergization of the magnet #9 spring 82 is adapted to seat the valve 12 and to unseat the valve lI for thereby opening the chamber 66 below valve piston 6! and the reservoir 61 to the atmosphere through the restricted port TI and past the magnet valve II to vent port 14 and whistle I5.

The straight air. suppression valve device I0 comprises a casing containing a pair of'flexible diaphragms 85 and-8'5 arranged in spaced relation with respect to each other. The adjacent faces of the two diaphragms 85 and 85 engage, respectively, two followers 87 and 88 provided on the opposite ends of a stem 89. i The stem 89 is suitably notched to receive a slide valve 99 which is adapted to be moved with the stem upon deflection of the diaphragms 85 and 95. The stem 89 and slide valve 99 are contained in a chamber 9| which is in constant communication with the atmosphere through a restricted vent port-92. Directly over the slide valve 99 the stem 89 is provided withan aperture 93 and through this aperture a rocking pin 94 extends and engages the slide valve within a suitable recess.

At the outer face of diaphragm 85 there is a chamber I which is connected by a passage IEII to a passage I I32 one end of which terminates at the seat of slide valve 90 while the other end is connected to a pipe I 03 leading to the straight air pipe 33. At the outer face of thediaphragm 85 is a chamber we which is connected by a passage IBE to a volume chamber or reservoir I06 and to the side outlet of a double check valve I111.

The casing is provided in chamber I04 with an annular collar I08 and mounted to slide through this collar is a spring cage or seat I99 which has an annular flange disposed below the collar I98 and adapted to engage same for limiting movement of the cage in an upwardly direction. Interposed between the cage and the lower end of the casing is a spring I I9 for urging the cage into engagement with collar I98. A plunger III having one end slidably mounted in a suitable bore in the casing extends through an aperture provided centrally in the spring cage I 99 into on- The opposite end of the rocking pin 94 is preferably ball shaped gagement with the lower face of diaphragm 83. Acollar H2 is provided on the plunger III within the spring cage I09 and a spring H3 is provided to act on said collar for urging same into engagement with the spring cage and for thereby urging the plunger I I I to its normal position shown. The end of the portion of the plunger III extending through the springcage I09 engages the outer face'of the diaphragm 66. With the collar H2 in engagement with the spring cage I99 and with said spring cage engaging the collar I98 on the casing, said plunger andzlugs II4 extending into the chamber I for engagment by diaphragm 85 define the normal position of diaphragms 86 and 85 and thereby of the slide valve 90.

One end of the double check valve I01 is connected to a passage II'I which leads to the seat of slide valve 43 and which is also connected to a pipe H8 leading to the double check device 6. The other end of the double check valve I0? is connected to a passage H9 and a spring H3 is provided to act on this end of the double check valve.

The straight air suppression valve device also comprises a flexible diaphragm I29 having at one side a chamber I2I in constant communication with the atmosphere through a restricted port I22 and containing a spring I23 acting on the diaphragm for urging it in a downwardly direction. At the opposite side of the diaphragm and engaging same is a poppet valve I24 arranged to engage an annular seat rib I25 the diameter of which is considerably less than that of the diaphragm I20. chamber I23 which is open through a choke I2! to passage II9. Within the seat rib I25 there is a chamber I28 which is connected to a passage I29 leading to the seat of slide valve 90.

The straight air suppression valve device further comprises a flexible diaphragm I30 having at one side a chamber I3I connected through a choke I32 vvlth passage II! and containing a spring I33 which acts on the diaphragm for urging same in a downwardly direction. At the opposite side of diaphragm I30 is a chamber I34 which is open to the atmosphere through a choke I35 and which contains a check valve I33 one face of which engages the diaphragm while the opposite face is arranged to engage an annular seat rib I3I. Within the seat rib is a chamber I38 in direct communication with the passage I I9 which is connected to the passage I29 through a choke I40.

Operation of embodiment shown in Fig. 1

Let it be assumed that the main reservoir l is charged with fluid under pressure in the usual manner and that the feed valve device 0 is supplying fluid at the usual reduced pressure from the main reservoir to pipe I4 leading to the brake valve device I, to the application and release magnet valve device 3 and to valve chamber 41 in the application valve device 4. Let it also be assumed that the feed valve device 8 is supplying fluid at the desired reduced pressure from the main reservoir I to the valve chamber 80 in the timing valve device 5.

With the train control magnet I0 energized fluid under pressure will therefore be supplied from chamber 80 to the volume reservoir Bl and to chamber 63 beneath the valve piston 6| to hold said valve piston and thereby the double beat valve 52 in their upper positions shown and above described. With the double beat valve 52 thus The valve I24 is contained in a seated in its upper position, the vent communication through pipe 49 from the application piston chamber'40 is closed and fluid under pressure Engineers straight air application of brakes If the engineer desires to effect a straight air application of brakes on the locomotive and cars of the train he turns the brake Valve handle I2 from release position into the application and release zone for thereby operating the self-lapping application and release valve portion II of the brake valve device to supply fluid under pressure to the straight air control pipe I3 at a pressure dependent upon the extent of movement of handle I2 into said zone.

The fluid pressure thus supplied to the pipe I3 flows through the double check valve device 6 to pipe 3I and then into diaphragm chamber of the master switch device 2. This pressure acting on diaphragm 2I deflects same in the direction of the right hand and thereby operates the stem 29 to shift the movable contact into engagement first with the contact finger 38 and then into engagement with the contact finger 39. As a consequence, the release train wire is first energized and then the application train wire M becomes energized.

On the locomotive the release magnet valve portion 43 of the application and release magnet device 3 is energized by current supplied to the release train wire 40 and operates to close the vent communication from the straight air pipe 33, and immediately following, the application magnet valve portion 42 is energized by current supplied to the application train wire 4| and operates to supply fluid under pressure to the straight air pipe 33, and this fluid pressure is adapted to act through a branch pipe I42 on the brake controlling valve device (not shown) on the locomotive to apply the locomotive brakes.

Fluid under pressure supplied to the straight air pipe 33 flows therefrom into diaphragm chamber 32 of the magnet switch device 2 and acts on the diaphragm 28 in opposition to the control pressure in chamber 30 acting on the diaphragm 21. The application and release magnet valve device 4 operates to continue the supply of fluid under pressure to the straight air pipe 33 and thus to chamber 32 until the pressure in said chamber equals or slightly exceeds that in diaphragm chamber 30, at which time the diaphragm 28 is operated to move the contact 35 in the direction of the left hand out of engagement with the finger 39.

The application train wire M is consequently deenergized and likewise the application magnet valve portion 42 so as to cut off further supply of fluid under pressure to the straight air pipe 33 for thereby limiting the degree of straight air pipe pressure to substantially the same degree as provided in the straight air control pipe I3 so that the degree of application of brakes on the locomotive will correspond to the position of the brake valve handle I2 in the application and release zone.

As soon as the supply of fluid under pressure to the straight air pipe 33 is terminated as just described, movement of the diaphragm 28 in the master switch device 2 ceases and the movable contact 35 thus remains in contact with finger 38 thereby maintaining the release train wire 40 and the release magnet valve portion 43 of the application and release magnet valve device 3 in an energized condition so as to hold the fluid pressure in the straight air pipe 33 to thereby hold the brakes on the locomotive applied.

In case the engineer desires to increase the clegree of brake application on the locomotive and cars of the train he operates the handle l2 further into the application and release zone to increase the pressure of fluid in the straight air control pipe H3. The master switch device 2 and the application and release magnet valve device 3 then operate as above described to provide a proportionate increase in pressure in the straight air pipe 33 and as a result a proportionate increase in the degree of brake application.

When the engineer desires to release the application of brakes on the locomotive and cars of the train he moves the brake valve handle l2 back toward its normal position shown and thus causes the self-lapping application and release valve portion H of the brake valve device to reduce the pressure of fluid in the straight air control pipe [3 and thereby in the diaphragm cham-' ber 36 of the master switch device 2, accordingly. When the pressure in chamber 38 is thus reduced the higher straight air pipe pressure in chamber 32 deflects the diaphragm 23 back 'to its normal position out of contact with both of the fingers 38 and 39. Both the application and release magnet portions 42 and d3 of the application and release magnet valve device 3 are as a consequence deenergizd and permits fluid under pressure to be vented from the straight air pipe 33 for thereby effecting a release of the brakes on the locomotive.

Automatic train control application of brakes With the brakes on the locomotive released and all parts of the apparatus in the normal positions as shown and with the locomotive and train running along a trackway, if the traflic conditions become unfavorable, as indicated by an adverse track signal, the train control magnet will become deenergized and permit spring 82 to seat valve 72 and to unseat valve ii. Upon the unseating of valve 11 fluid under pressure is vented from chamber 66 at the lower face of piston H and from the connected volume reservoir 61 through choke Tl, chamber past the valve 1| to chamber 13 and then to atmosphere through the vent port M and the signal whistle 15. When the pressure of fluid is thus reduced in chamber 67 sufficiently, the spring 53 moves the valve piston 6! from the position shown downwardly into engagement with a gasket M3.

The combined volumes of chamber 65 and reservoir 67 are so related to the flow capacity of the choke ii that the Valve piston 6! will not be moved to its lower position as just described until after a certain period of time, such as six seconds, has elapsed from the deenergization of the magnet 78, for reasons which will be later brought out.

When the valve piston 6! is thus moved to its lower position, spring 59 shifts the double beat to the straight air suppression valve device Ill. The pipe 54 is normally opened to the atmosphere through a cavity M4 in slide valve and thence through a passage M5, past a check valve [45 and through a passage I47 which is connected to pipe I! which in turn is open to the atmosphere past the poppet valve H: in the brake valve device with the brake valve handle ii in its normal position. Under this condition therefore fluid under pressure will be vented from the application piston chamber 38 and when thus reduced to a suilicient degree below that in valve chamber 13?, the differential of fluid pressures created on the application piston will move same and-thereby the slide valve it against the spring 5|] in an upwardly direction to an application position defined by engagement of the piston with a gasket M8. 7

In application position of the application slide valve 36 a passage M9, which in the normal position of said valve is open to the atmosphere through a port I59 in the valve and a vent passage i5l, is uncovered by the lower end of the valve and opened to the valve chamber 47 where-, upon fluid at feed valve pressure flows from said valve chamber to passage M9 and then to pipe H8 leading to the double check valve device 8. Fluid pressure thus supplied to the double check valve device flows through same and pipe 3i to chamber 35 in the master switch device 2 and therein acts to operate same to cause the application and release magnet valve device 3 to supply fluid to the straight air pipe 33 at a pressure equal to that supplied from feed valve device 9 to chamber 33, for thereby providing a full straight air application'of the brakes on the locomotive and cars of the train.

In the application'position of slide valve. 45 a cavity I52 therein connects a passage I53 from the application piston chamber 48 directly to passage 141 which is open through pipe I? and past the poppet valve [5 in the brake valve device I to the atmosphere, so that the application piston 45 and slide valve Mi will remain in application position and hold the brakes on the locotive and train applied as long as the brake valve handle I2 is in release position, even though, subsequent to the automatic application of brakes being initiated, the magnet 10 should become energized in response to a favorable track signal, since it will be noted that the vent from the application piston chamber 28 by way of cavity l53 in the slide valve 46 by-passes the vent communi-.- cation through the timing valve device 5.

Release of automatic train control application of brakes In order to release an application of brakes effected in the manner just described, it is necessary that the engineer move the brake valve handle l2 from the release position into the application and release zone to permitseating of the poppet valve IS, the parts being so designed that said valve will become seated when the handle is so positioned in said zone as to provide substantially a full straight air application of brakes on the locomotive and whenin this position it will be apparent that fluid under pressure will be supplied by the straight air application and release valve portion II of the brake valve device to the straight air control pipe l3. 7

When the poppet valve I5 is seated as just de scribed, fluidunder pressure flowing through the port Ml in the application piston 45 into piston chamber 48 and thereby into. the communication connecting said chamber with the poppet valve chamber I6 in the brake valve device builds up the pressure therein and when increased sufficiently the spring 50 acts to move the piston 45 and slide valve 45 back to their normal positions shown. Upon the return of slide valve 45 to its normal position, pipe II8 leading to the double check valve device 6 is vented to the atmosphere through the vent port I5I and with fluid under pressure supplied to the straight air control pipe I3 by the brake valve device, the double check valve device 5 will then be operated to supply fluid from the pipe I3 to the master switch device 2 for thereby maintaining'the brakes on the locomotive applied so long as the brake valve handle I2 is held in the application zone. It will be noted that upon return of the application slide valve 45 to its normal position the vent from piston chamber 43 byway of passage I53 to passage I 61 is closed so that when desired the engineer may return the brake valve handle I2 to its release position for releasing the brakes on the locomotive and cars of the train and in which the poppet valve I5 is again unseated.

Straight air suppression of brake application valve device 4 controlled magnet I and movement of the double beat valve 52 to its lower position. Also, promptly upon deenergization of the magnet .10 fluid un' der pressure is supplied to the whistle I for operating same to call the engineers attention to the situation, so that he may before expiration of this time period, operate thebrake valve device to initiate the application of brakes.

If the brake valve device is thus operated to supply fluid under pressure to the straight air pipe for initiating the application of brakes on the locomotive and cars of the train fiuid pressure from the straight air pipe flows through the branch pipe I93 and passages Hi2 and Ifll to diaphragm chamber If!!! in the straight air suppression valve dveice I8 and. therein acts on the diaphragm 85 to effect movement thereof and thereby of stem 85 and slide valve 95 in a downwardly direction against the opposing pressure of spring I I3 and into engagement with the spring cage I09. In this temporary position communication is closed between pipe 54 from the timing valve device 5 and passage I45 so that upon subsequent movement of the double beat valve 52 in the timing valve device to its lower position fluid under pressure cannot be vented from the application piston chamber 48. Thus if an application of the brakes is promptly initiated by the engineer by operating the brake valve device I, the application piston 45 and slide valve 46 will be prevented from moving from their normal position upon movement of the double beat valve 52 to its lower seated position. 7

At the same time as fluid under pressur is supplied to diaphragm chamber I69 in the straight air suppression valve device I 0 and in the temporary suppression position thereof just described, fluid under pressure from the straight air pipe also flows through the passage I02 and ber Hit it also flows at a restricted rate through choke I40 to diaphragm chamber I94 and to the reservoir I05 for thereby charging said chamber and reservoir at a rate which is sufiiciently slow to insure obtaining an adequate differential between the fluid pressure in diaphragm chambers 40!] and M4 to move the diaphragms'and slide valve to and to then hold same in the temporary suppression position defined by the spring stop I05, as just described.

It will be noted that if the engineerattempts to limit the application of brakes on the locomotive by limiting the pressure of fluid supplied to the straight air pipe the pressure in diaphragm chamber I64 will tend to become equalized with that in diaphragm chamber I00 in which case the spring I I 3 would return the suppression slide valve 9!] to its normal position. The application piston chamber 48 would then be vented and an automatic train control application of the brakes would occur, unless in the meantime, the track signal had become favorable and caused seating of the double beat valve 52 in the timing valve device 5 in its upper position. Thus if the track signal remains adverse the engineer is obliged to continu operation of the brake valve device 5 to initially supply fluid under pressure to the straight air pipe 33 and thereby to the diaphragm chamber I00 in the suppression valve device at a rate which will maintain said pressure sufficiently higher than that in diaphragm chamber I04 to hold the parts of the suppression valve device in the temporary suppression position against the pressure of spring I I3.

The flow capacity of choke I43 and the combined volumes of reservoir I06 and diaphragm chamber I04 are so related however that after providing an initial pressure in the straight air pipe 33, such for instance as fifteen or twenty pounds to initiate the application of brakes on the locomotive and train the engineer may stop the supplyof fluid under pressure to the straight air pipe for a certain limited period of time, such as two or three seconds, during which the pressure in the diaphragm chamber I04 will not become increased sufiiciently through the choke I40 for the spring II3 to move the parts of the straight air suppression valv device back to their normal position. This slight lapse of time will permit the gathering of slack in the train due to the initial stage of brake application in case there is looseness in the couplers between the cars in the train, and such a lapse of time is also considered desirable to avoid excessive initial braking of the vehicle wheels with the attendant possibility of sliding of the wheels. More specifically, at the time an application of brakes is initiated the brake shoes and vehicle wheels will usually be relatively cool so-that a relatively high coeflicient of friction will b eflfective. Limiting the degree of the initial step of brake ap--- plication will, however, provide for sufllcient heating of the shoes and wheels to reduce the coefficient of friction before the expiration of the period of time above mentioned to such a degree that a subsequent increase in brake application to a degree'required to provide a de-' sired rate of retardation will not cause the wheels to slide.

Before th termination of the slight lapse of time following the initial step of increase in pressure in the straight air pipe 33, it is therefore necessary that the engineer continue operation of the brake valve device I to effect a further increase in the pressure of fluid in the straight air pipe 33 for increasing the degree of brake application on the locomotive and train and also for increasing the pressure on the diaphragm 85 in chamber I of the independent suppression valve device I0 for insuring against movement thereof back to its normal position.

As above mentioned, the supply of fluid under pressure to the diaphragm chamber I00 is so restricted by the choke I40 upon initiating the straight air application of the brakes with re spect to the build up in pressure in the diaphragm chamber I00 as to insure operation of the independent suppression valve device to prevent operation of the brake application valve device 4 when the engineer initiates a straight air application of brakes as intended, and also said chok determines the rate at which the straight air pipe pressure must be increased to maintain the suppression valve device in the temporary suppression position.

After the pressure in the straight air pipe 33 has been increased to a degree slightly exceeding the initial step of brake application, this pressure acting through the passage I29 in chamber I on the check valve I20 overcomes the opposing pressure of spring I23 and moves said valve away from the seat rib I25. The pressure of fluid from chamber I28 then equalizes into the chamber I26 onthe diaphragm I20 and since the area of the diaphragm is'greater than that of the valve originally exposed to the pressure in chamber I28 before unseating thereof, said pressure acting on this greater area causes prompt deflection of the diaphragm against the spring I23 and thereby full seating movement of the check valve I20. Fluid under pressure supplied from the straight air pipe to passage I29 then flows through the check valve chamber I and choke I21 to passage H9 and then past the double check valve I01 to the volve reservoir I06 and also to the diaphragm chamber I04. It will be noted that the supply of fluid through the choke I 21 is in parallel with that through choke I40 so that due'to the combined capacities of the chokes'the pressure in chamber I06 and in diaphragm chamber I04 Will build up more rapidly than prior to the unseating of the check valve I20. essential for the engineer to increase the rate at which fluid under pressure is supplied to the straight air pipe 33 and thereby to diaphragm chamber I00 in order to maintain a sufficient differential between the fluid pressures in chambers I00 and I04 to hold the parts of the independent suppression valve device in the temporary suppression position. This is desirable in order to enforce the engineer to apply the brakes on the locomotive and cars of the train with sufiicient rapidity to insure that the train will be decelerated and possibly brought to a stop in substantially the same time as if the brakes were applied by operation of the brake application valve device 4. I It will now be noted that at the time the brake application is initiated the engineer may cause the brakes to be applied at a relatively It is therefore slow rate for the purpose of gathering slack in the train and to avoid the possibility-of slipping wheels but after the initial step of application is completed the engineer must then apply the brakes at a sufficiently faster rate to insure the safety of the train.

When "by operation of the'brake valve device the straight air pipe pressure has been increased to a predetermined relatively high degree such for instance as sixty pounds, which is adequate to insure the safety of the train, such pressure acting through passage H9 in chamber 138 on the check valve I36 is adapted to move said check valve away from the seat rib I 31 against the opposing pressure of spring I33. When the check valve I30 is thus unseated fluid pressure flows from chamber I38 into chamber I34 and acts on the area of diaphragm I30, which is greater than that of the check valve previously'subject to said fluid pressure, and as a result, the diaphragm I30 is promptly deflected in an upwardly direction to a suflicient extent to provide for full unseating of the check valve I30.

When the check valve I30 is thus unseated,

I fluid under pressure is then ventedfrom the diaphragm chamber I04 and from the volume cham ber or reservoir I00 past the upper end of the double check valve I01, through passage I I 9 to chamber I38 and thence through chamber I30 to the atmosphere through the restricted vent I35. When the pressure of fluid in the diaphragm chamber I04 is thus sufficiently reduced, fluid at straight air pipe pressure acting in diaphragm chamber I00 on the diaphragm 05 and I through the stem 89 on the spring I I3 and spring cage I00 overcomes the opposing pressure of spring I I0 acting on said spring cage and moves said diaphragm and thereby the stem 89 and slide valve 00 from the temporary suppression position to a permanent suppression position which may be defined by engagement of the follower 01 with the casing. In this permanent suppression position communication is closed between passages I02 and I23 so as to prevent further flow of fluid under pressure to the volume reservoir I00 and to chamber I04, and the cavity I54 in slide valve 00 connects passage I29 to an atmospheric vent port I56 whereupon fluid pressure is completely vented from said chamber and reservoir. Straight air pipe pressure in diaphragm chamber I00 is then eflective to maintain'the parts of the suppression valve device in the permanent suppression position against the opposing pressures of springs I I3 and H0 without any further increase in straight air pipe pressure. I It will thus be seen that if the engineer applies the brakes with a suflicient degree of force to insure unseating of the check valve I30 the suppression valve device will be conditioned to maintain the suppression slide valve .90 in the permanent suppression position without any further increase in the degree of brake application. In this permanent. suppression position the venting communication from the application pisten chamber 48 byway of the double beat valve 52 in the timing valve device 5 is maintained closed the same as during temporary supprese sion so that the brake application valve device 4 cannot operate to effect an automatic train control application of the brakes so long as the brakes are held applied as just mentioned and the track signals remain unfavorable. 7

The vent passage I from" the check valve chamber I34 is choked so as to offer such re istchamber with respect to the rate'at which fluid is supplied to said chamber past valve I36, that the pressure in said chamber will be increased to such a degree as to cause thediaphragm I36 to deflect sufficiently against spring I33 to permit full opening of the check valve [36. This prompt and full opening movement of the check vlave I36 isthus dependent upon theventing ca pacity of choked passage I35 and upon the prompt and relatively rapid inflow of fluid to chamber I34 upon unseating of check valve I36, and such rapid inflow is obtained from the diaphragm chamber I84 and volume reservoir I06 through the communication past the upper end of the double check valve I51 having a relatively great flow capacity.

It will be noted that the check valve I36 will remain Open only as long as the fluid pressure in chamber I34 is able to overcome the pressure of spring I33 and after this pressure has become reduced sufliciently. the spring I33 will return the check valve I36 into seating engagement with theseat rib I31. Beforethis occurs however the suppression slidevalve 98 willhave obtained its permanent. suppression position connecting the diaphragm chamber I04 and the volume reservoir I56 to the atmosphere by way of the vent port I56, as above described, so that the diaphragm chamber I54 will be maintained at atmospheric pressure even after closing of check valve I36.

After the brakes on the locomotive have been applied, as just described, and the suppression valve device It has assumed its permanent suppression position .the brakes on the locomotive and train cannot-be released until after the track signals have become favorable to effect energization of the application magnet I5. If the engineer attempts to eflect a release of brakes prior to this occurring, then just as soon as the straight air pipe pressure acting in chamber I09 of the straight air suppression valve device is reduced sufficiently the opposing pressure of spring II3 will return the suppression slide valve 90 to its normal position shown and thereby open the vent communication from the application piston chamber 48 to the atmosphere by way of the poppet valve I5, and as a result an automatic application of the brakes will occur.

However, after the application magnet I5 becomes energized due to a favorable track signal and the valve piston 6i operates to move the double beat valve52 to its upper seated position for thereby closing the vent communication from the application piston chamber 48, thenthe engineer may operate the brake valve device I to eflect a complete release of fluid under pressure from thestraight air pipe 33. and thereby obtain a complete release ofbrakes on the locomotive and cars of the train. In effecting a release of brakes as just mentioned the parts of the straight air suppression valve device will be returned to their normal position by the pressure of spring II3 so as to be in condition for operation when again required.

Prevention of suppression of the brake application valve device If the engineer fails to operate the brake valve device I to effect an application of brakes on the locomotive and cars of the train and thereby obtain operation of the independent suppression valve device It prior to the movement of the application piston 45 and slide valve 46 to their application positions in response to an adverse anceto outflow or -fluid under pressure from said track signal, then the brakes on the locomotive and cars of the train will be applied by operation of the application valve device 4 in the manner before described. Under this condition operation of the brake valve device I by the engineer cannot effect operation of the straight air suppression valve device It to close the vent communication from the application piston chamber 48 since in the application position of the application slide valve 46 fluid pressure supplied to passage I49 for effecting operation of the master switch devicealso flows through passage II! to the lower face of the double check valve I5! and effects movement thereof against spring I20 to its upper seated-position. In this position passage II? is connected to passage I so that at the same time fluid pressure is supplied to the master switch device fluid under pressure also flows to diaphragm'chamber I84 and acting on the diaphragm 85 will maintain slide valve in its normal position against straight air pipe pressure which will be obtained in the diaphragm chamber. Hill. Thus suppression of the brake application valve device 4 cannot be prevented unlessthe engineer operates the brake valve device prior to movement of the .brake application valve device 4 to the application position.

Whenan automatic train control application of brakes is effected by operation of the application piston 45 and slide valve 46 it will be apparent that with the brake valve handle in release position there will be a leak of fluid under pressure past the poppet valve I5 to an extent limited by the capacity of choke MI in the application piston 45 to supply fluid from the valve chamber 41 to the piston chamber 48. This leak however may be stopped by the engineer turning the. brake valve handle I2 into the application and release zone to permit seating of the poppet valve I5. Under this condition fluid pressure vented from the application piston chamber I48 through the timing valve device and suppression slide valve 98 to passage I45 will flow into a stop reservoir I58 and eventually equalize therein with the pressure in the application valve chamber 41. When the pressure in the application piston chamber 48 is thus increased sufficiently, spring 58. will return the application piston 45 and slide valve 46 to their normal positions.

The volume of the stop reservoir I58 is however so related to the flow capacity of the restricted port MI in the application piston 45 that a sufiicient increase in the fluid pressure in the piston chamber 48 will not be obtained to permit spring 50 to return the application piston 45 andslide valve 46 to their. normal positions until after a sufficient period of time has elapsed to insure an increase in pressure to diaphragm chamber 30 of the master switch device to a degree which will efiect a full straight air application of the brakes on the locomotive and cars of the train.

When the piston 45 and slide valve 46 are returned to their normal positions .it will be noted that pipe II8 through which fluid under pressure was supplied for applying the brakes will be vented, but a release of the brakes will not occur since with the brake valve handle I2 in the position providing for seating of the check valve I5, said brake valve device provides a sufl'icient pressure in the straight air control pipe I3 to insure safe braking of the train .andthis pressure, acts upon venting of pipe II8 to shift the double checek valve device 6 to the position opposite that shown and then equalizes through pipe 3| into diaphragm chamber 30 of the master switch device 2 to maintain the brakes on the locomotive and on the cars of the train applied.

The port 92 connecting the valve chamber 9I in the independent suppression valve device I to the atmosphere is restricted as above mentioned in order to minimize loss of fluid under pressure from said chamber in case of breakage of either of the diaphragms 85 and 36. It will be noted that any such loss might be from the straight air pipe 33 by way of diaphragm chamher I 00 and it is therefore important to reduce the degree of such possible loss to a point where it would not interfere with obtaining a straight air application of the brakes.

The restricted port I22 in the atmospheric vent from diaphragm chamber I20 is likewise provided to limit the loss of fluid pressure from the straight air pipe in case of breakage of the diaphragm I22, while the choke I32 between the diaphragm chamber I3I and passage I I7 is adapted to minimize loss of fluid pressure supplied, to said passage by the application valve 46 in its application position, past the diaphragm I38 in case of breakage thereof.

Embodiment of invention shown in Fig. 2 Description of parts In this embodiment of the invention communication between pipes 54 and passage I45, through which fluid under pressure is adapted to be vented from the application piston chamber 48 for eifecting an automatic train control application of the brakes, is controlled by a check valve I 59 which is disposed in a chamber I60 open to the passage I45 and which is adapted to be moved into seating engagement with a seat rib Itl for closing the communication. A flexible diaphragm IE2 is provided for operating the check valve I59, said diaphragm having one face open to chamber I88 and having at the opposite face a chamber I63 connecting by a passage I64 to the seat of a suppression slide valve I65.

The slide valve I65 corresponds generally to the slide valve 90 shown in Fig. l and is arranged to be operated by a stem I56 which at one end is operatively connected to diaphragm 85 for movement therewith. Adjacent its other end,

the stem I55 is provided with an annular collar I67 upon which acts a temporary suppression spring I58. The stem I55 is provided with a reduced portion between the collar I67 and a shoulder I59 which extends through an aperture provided in a spring cage I70 having an outwardly extending annular flange adapted to engage a stop ring Ill secured in the casing. A permanent suppression spring I72 acts on the cage E75 urging same into engagement with the stop ring Ill and is adapted to oppose movement of the cage in the opposite direction.

The diaphragm 35 has at its outer face the chamber I all which is connected through passages ill! and IE2 to the straight air pipe 35. The slide valve IE5 is contained in a chamber 73 at the opposite side of the diaphragm 85 which chamber however is not vented as in the structure shown in Fig. 1, but instead, is connected to passage I49 leading to the seat of the application slide valve 46 through a restricted communication I74. With the slide valve I55 in its normal position shown passage I52 communicating with the straight air pipe 53 is open through a cavity I75 in slide valve I65 to volume chamber or reservoir I76. The slide valve is provided with a cavity I77 which in the normal position of the valve connects passage I62 from diaphragm chamber I63 to the atmosphere through a restricted vent port I78.

Operation of embodiment shown in Fig. 2

When an automatic application of the brakes is eifectedby operation of theapplication valve device l in response to deenergization of the magnet 7E3, the venting of fluid under pressure from the application piston chamber 48 is adapted to occur through the timing valve device 5 to pipe 54 as before described. In the structure shown in Fig. 2 the pipe 54 is normally open to the check valve chamber I 60 so that with the check valve I59 unseated, as shown, fluid pressure vented from the application piston cham-' ber 48 to the check valve chamber I60 will flow therefrom to passage I 45 and then to the atmosphere past the poppet valve I5 with the brake valve handle I2 in its normal release position. The brake application piston 45 and slide valve 45 will then move to their application position and effect a straight air application of the brakes on the locomotive and cars of the train as before described.

In the application position of the slide valve 46 fluid under pressure supplied to passage I49 for effecting the application of brakes will also flow through the restricted communication I74 into valve chamber I73 of the independent suppression valve device and therein acting on the lower face of the suppression diaphragm 85 will maintain said diaphragm and thereby the slide valve I55 in their normal position shown incase an attempt is made by the engineer to suppress operation of the application piston and slide valve by operating the brake valve device to ap ply the brake, as will be presently described,

The choke is provided in the communication I7 3 so that in case of leakage or breakage of the diaphragm 85 when a straight air application of the brakes is effected by operation of the brake valve device I, fluid pressurefrom the straight air pipe 33 and diaphragm chamber I80 which may thus leak into the chamber I73 will be restricted in its escape therefrom through passage I59 and vent port I5I under the application slide valve 46 so that such leak will not have any material eifect upon the straight air pipe pressure.

In case the engineer desires to suppress operation of the application piston 45 and slide valve 66 upon deenergization of magnet 70 in response to an unfavorable track signal, he may operate the brake valve device I to eifect a supply of fluid under pressure to the straight air pipe in two separate stages for thereby effecting a two-stage application of brakes in the manner before described.

When fluid under pressure is supplied to the straight air pipe by operation of the brake valve device as just mentioned, fluid flows from the straight air pipe through passages I52 and IflI into diaphragm chamber IIlO of the independent suppression valve device and also from passage I52 through cavity I75 in slide valve I55 to the volume reservoir I76 for thereby charging said reservoir with fluid at substantially the same pressure as acting in the straight air pipe.

The preliminary suppression spring I68 acting on the diaphragm stem IE6 is adapted to maintain said stem and thereby the slide valve I65 and diaphragm in their normal positions shown until the straight air pipe pressure has been increased to a desired degree such as 15 or 20 pounds representing the first step of the application. When such a degree of pressure is obtained in the diaphragm chamber I50 the diaphragm is deflected downwardly against the opposing pressure of the preliminary suppression spring I68 until the shoulder I69 on the stem engages the spring cage which defines the temporary suppression position of the device. The pressure of the permanent suppression spring I12 on the spring cage I10 is such as to prevent further downward movement of the stem I55 by thein a upwardly direction for moving the check 1 valve I55 into engagement with the seat rib I6! for closing communication between pipe 54 from the timing valve device to passage I45, If the check valve I59 is thus seated prior to movement of the double beat valve 52 in the timing valve device 5 to its lower seated position fluid under pressure will not be vented from the application piston chamber 48 in the application valve device 4 and as a result the application valve device will not operate to effect an automatic application of the brakes.

It will be noted that while fluid under pressure from the volume reservoir I16 is acting in chamber I63 to hold the check valve I59 seated, it is also being vented to the atmosphere at a coni trolled rate through the restricted vent port I18 and the flow capacity of this vent port is so related to the volume of the reservoir I'IB as to maintain suiflcient pressure in chamber I53 for holding the check valve I59 seated against the opposing pressure of fluid in pipe 54 from the application piston chamber I23 for a period of time suflicient to permit gathering of the train slack et cetera, as hereinbeiore mentioned in connection with the device shown in Fig. 1. In

case the slide valve I55 remains in the preliminary suppression position for a longer period of time, then the pressure of fluid supplied through pipe 54 will unseat the check valve I59 and be vented to cause the application Valve device 4 to operate to effect a straight air application of the brakes.

If, however, before the expiration of this time period the operator actuates the brake valve de- Vice 5 to increase the straight air pipe pressure to a degree such as sixty pounds which will insure the safety of the locomotive and cars of the train, this increased pressure acting in chamber its on the diaphragm 85 will overcome the opposing pressure of the permanent suppression spring I52 and move the stem I66 and thereby slide valve I55 to a permanent suppression position determined by engagement between the follower at the lower face of diaphragm I60 and the casing.

In this permanent suppression position of slide valve IS5, the cavity F1 is adapted to connect the straight air pipe passage I52 to passage I64 so that fluid under pressure will be supplied directiy from the straight air pipe 33 to diaphragm chamber N53 for maintaining the check valve I59 seated to thus prevent operation of the application piston 45 and slide valve 4% to their application positions so long as the brakes are maintained applied with a suflicient degree of force to hold the suppression valve device in the permanent suppression position.

When the track signal again becomes favorable and the magnet "I0 is as a result again energized and the double beat valve 52 ismoved to its upper seated position for closing the vent from the application piston chamber 48, the engineer may then operate the brake valve device i to effect a release of fluid under pressure from the straight air pipe 33 and thereby from diaphragm chamber IE5 in the independent suppression valve device. The brakes on the locomotive and cars of the train will be thus released, and due to action of springs IE8 and I12 in the independent suppression valve device the parts thereof will be returned to their normal position.

Summary It will now be noted that, by the use of either form oi independent suppression valve device, the engineer may by proper operation of the brake valve device I to effect an electropneumatic straight air application of brakes on the locomotive and cars of a train, prevent operation of the brake application valve device 4, and such application of brakes may be efiected in two steps with an intervening lapse of time between the steps in order to avoid harsh gathering of the slack in the train in case such exists, and also to avoid the possibility of sliding of wheels as might occur in case the application were effected in one continuous stage. The independent suppression valve devices not only avoid the difiiculties just mentioned but also permit a certain flexibility in effecting a brake application so as to avoid an excessive rate of development of deceleration which might be uncomfortable to passengers in a train. It should however be noted that in order to obtain permanent suppression of the brake application valve device 4 the engineer must apply the brakes to a suflicient degree to insure the safety of the train within a lapse of time which will slow down the train or bring it to a stop substantially as soon as if the application were due to automatic operation of the brake application valve device 4 upon deenergization of the magnet III.

While only two embodiments of the invention have been shown and described in detail, it is not the intention to limit the scope to these embodiments or otherwise than by the terms of the appended claims.

Having now described my invention, what I claim as new and desire to secure by Letters Patent, is?

1. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to eiiect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for efiecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, suppression means subject to the pressure in said straight air pipe and operative upon an increase in pressure therein to a predetermined degree within a chosen interval of time to render said train control means ineffective, said suppression means including means for rendering said train control means effective upon a less increase in straight air pipe pressure in said interval of time, and means set in operation upon initiating a straight air application of brakes for controlling said interval of time. 7

2. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to efiect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, suppression means subject to the pressure in said straight air pipe and operative upon an increase in pressure therein to a predetermined degree within a chosen interval of time to render said train control means ineflective, said suppression means including means for rendering said train control means eifective upon a less increase in straight air pipe pressure in said interval of time, and means set in operation upon initiating a straight air application of brakes for controlling said interval of time, operation of said train control means being adapted to render said suppression means non-operative by fluid supplied to said straight air pipe.

3. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means controlled by the pressure of fluid in said straight air pipe for rendering said train control means either eifective or ineffective, said suppression means including timing means set in operation upon supplying fluid under pressure to said straight air pipe for rendering said train control means ineifective for a chosen interval of time, said suppression means being operable by straight air pipe pressure when increased to a predetermined degree prior to termination of said interval of time to maintain said train control means ineffective, and means operable after termination of said interval of time with straight air pressure less than said predetermined degree to render said train control means effective.

4. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means for rendering said train control means ineffective, said suppression means including means controlled by an increase in pressure in said straight air pipe and by the pressure in a chamber which is varied at a desired rate upon supplying fluid under pressure to said straight air pipe and being operative upon a predetermined variation in pressure in said chamber to render said train control means effective, and said means being responsive to an increase in pressure in said straight air pipe to a chosen degree prior to said predetermined variation in pressure in said chamber to render the pressure in said chamber non-controllable and to maintain said train control means ineffective.

5. In a fluid pressure brake, in combination,

train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe in successive steps, and means conditionable upon the initial step of supply of fluid under pressure to said straight air pipe to render said train control means ineffective for a chosen interval of time, said means being conditionable by another step of increase in straight air pipe pressure prior to the termination of said interval of time to maintain said train control means ineffective.

6. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake Valve device operative to effect a supply of fluid under pressure to said straight air pipe in successive steps, suppression means for rendering said train control means ineffective for a period of time required to eifect a predetermined variation in pressure in a chamber, said suppression means being operative upon the initial supply of fluid under pressure to said straight air pipe to initiate the variation in pressure in said chamber and upon a further increase in pressure in said straight air pipe prior to termination of said period of time to maintain said train control means ineffective, said train control means being rendered eifective'upon failure of said further increase in straight air pipe pressure prior to termination of said period of time.

7. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device operative to efiect a supply of fluid under pressure to said straight air pipe, and suppression means subject to straight air pipe pressure and the opposing pressure of fluid in a chamber adapted to be supplied with fluid under pressure from said straight air pipe at a restricted rate, said suppression means being operative upon a chosen rate of increase in pressure in said straight air pipe with respect to the rate of increase in pressure in said chamber to render said train 'control means ineflective and being operative upon an increase in straight air pipe pressure to a chosen degree to render said chamber pressure ineflective, said chamber pressure being adapted upon a slower rate of increase in I pressure in said straight air pipe to condition said suppression means to render said train control means effective.

8. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means operative upon initiating the supply of fluid under pressure to said straight air pipe to initiate a variation in pressure in a chamber, the pressure in said chamber being adapted to render said train control means ineffective for a chosen interval of time, said supe pression means being operative upon an increase inv pressure in said straight air pipe to a chosen degree before termination of said interval of time to maintain said train control means ineffective as long as the straight air pipe pressure is maintained equal to said chosen degree.

.9. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means controlled by the pressure of fluid in said straight air pipe and oper ative upon a chosen rate of increase in pressure therein to render said train control means ineffective and operative by a chosen degree of straight air pipe pressure to maintain said train control means ineffective while the straight air pipe pressure is not lower than said chosen degree, said suppression means including means conditioned during the supply of fluid under pressure to said straightair pipe to render said train control means effective if the rate of increase in straight air pipe pressure is less than said chosen rate.

10. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for efiecting an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means controlled by the pressure of fluid in said straight air pipe and being operative upon a chosen rate of increase in straight air pipe pressure during an initial step of increase in straight air pipe pressure and upon a faster rate of increase during a subsequent step of increase in straight air pipe pressure to render said train control means ineffective and operative by straight air pipe pressure when increased to a chosen degree to maintain said train control means ineifectivasaid suppression means including means conditioned during the supply of fluid under pressure to said straight air pipe to render said train control means effective if the rate of increase in straight air pipe is less than said chosen rates.

11. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid pressure is adapted to be supplied to effect an application of brakes, an engineers brake valve device for effecting a supply of fluid under pressure to said straight air pipe, and suppression means having a normal position for rendering said train control means effective upon a change in track signals and movable upon supply of fluid under pressure to said straight air pipe by operation of said brake valve device to a temporary suppression position for rendering said train control means temporarily ineffective, said suppression means being movable upon a further supply of fluid under pressure to said straight air pipe by operation of said brake valve device to a permanent suppression position for maintaining said train control means ineffective during the application of the brakes, and timing means operative in said temporary suppression position for rendering said train control means effective after a chosen lapse of time upon failure of said further supply of fluid under pressure to said straight air pipe.

12. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of the'bralres, a straight air pipe to which fluid under pressure is adapted to be supplied to effect an application of the brakes, an engineers brake valve device for effecting a supply of fluid under pressure to said straight air pipe, and suppression means having a normal position for rendering said train control means effective upon a change in track signals and being movable therefrom upon a chosen initial increase in straight air pipe pressure to a temporary suppression position for rendering said train control means ineffective and operable by a higher pressure in said straight air pipe to maintain said train control means effective, and means conditioned during the initial increase in straight air pipe pressure to effect movement of said suppression means to said normal position after a chosen lapse of time upon failure to provide said higher pressure in said straight air pipe.

13. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied .to effect anapplication of brakes, an engineers brake valve device for effecting a supply of fluid under pressure to said straight air pipe, and suppression means having a normal position for rendering said train control means effective upon a change in track signals and movable upon a chosen initial increase in straight air pipe pressure to a temporary suppression position for rendering said train control means ineffective and responsive to a higher pressure in said straight air pipe to maintain said train control means ineffective, a chamber a predetermined variation in pressure in which is adapted to render said suppression means movable from said temporary suppression position to said normal position, said suppression means being operative upon said initial increase in straight air pipe pressure to initiate said variation in pressure in said chamber and upon said higher straight air pipe pressure prior to obtaining said predetermined variation to maintain said train control means ineffective, said suppression means being operative if said predetermined variation is obtained prior to said higher straight air pipe pressure to render said train control means effective.

14. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied to effect an application of brakes, an engineers brake valve device for effecting a supply of fluid under pressure to said straight air pipe, and sup pression means controlled by the differential between opposing fluid pressures in said straight air pipe and a volume for rendering said train control means either effective or ineffective, said suppression means normally venting said volume and being operative during an increase in straight air pipe pressure to supply fluid under pressure to said volume at a restricted rate and operative upon obtaining a predetermined pressure in said straight air pipe to cut off the supply of fluid under pressure to said volume and to vent the fluid under pressure therefrom, and means determining the rate of increase in straight air pipe pressure to provide the diflerential of fluid pressures required to render said train control means in-.

eflective and operative to render said .train control means effective on a less difierential.

15. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied to effect an application of brakes, an engineers brake valve device for eflecting a supply of fluid under pressure to said straight air pipe, suppression means controlled by the opposing fluid pressures in said straight air pipe and in a normally vented chamber for rendering said train control means either efiective or ineiiective upon a change in track signals, said suppression means being operative upon an initial supply of fluid under pressure to said straight air pipe to render said train control means ineffective and upon a further supply of fluid under pressure to said straight air pipe within a predetermined interval of time after the termination of the initial supply to maintain said train control means ineffective, and means set in operation upon the initial supply of fluid under pressure to said straight air pipe to render said train control means effective at the termination of said interval of time and adapted to be rendered inefiective upon said further supply of fluid under pressure to said straight air pipe within said interval of time, said train control means when eflective being operative to supply fluid under pressure to said normally vented chamber for rendering said suppression means non-responsive to pressure of fluid supplied to said straight air pipe.

16. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied to eflect an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means for rendering said train control means either eflective or ineffective upon a change in track signals, said suppression means comprising a movable abutment subject to straight air pipe pressure and the opposing in straight air pipe pressure exceeding the rate of increase in pressure in said chamber to render said train control means ineflective and operative when the pressure in said straight air pipe is increased to a predetermined degree to vent fluid under pressure from said chamber for locking said arrangement in said position.

18. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to eflect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied to effect an application or" brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means for rendering said train control means either eflective or ineflective upon a change in track signals, said suppression means including a movable abutment subject to variations in fluid pressure in said straight air pipe and an opposing fluid pressure in a chamber normally open to said straight air pipe through a restricted communication, and means operable by said abutment upon a chosen rate of increase in straight air pipe pressure exceeding the rate of increase in pressure in said chamber to render said train control means ineffective and operative when the pressure in said straight air pipe is increased to a predetermined degree to vent fluid under pressure from said chamber for locking said arrangement in said position, said pressure of fluid in a chamber and being movable by straight air pipe pressure to a suppression position for rendering said train control means ineflective, said train control means being adapted upon operation to supply fluid under pressure to said chamber to render said abutment non-responsive to straight air pipe pressure.

17. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to eifect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied to effect an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means for rendering said train control means either efiective or inefiective upon a change in track signals, said suppression means including a movable abutment subject to variations in fluid pressure in said straight air pipe and an opposing fluid pressure in a chamber normally open to said straight air pipe through a restricted communication, and means operable by said abutment upon a chosen rate of increase train control means being operative in eflecting an application of brakes to supply fluid under pressure to said chamber for rendering said abutment non-responsive to straight air pipe pressure.

19. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied to effect an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means for rendering said train control means either effective or ineffective upon a change in track signals, said suppression means including a movable abutment subject to variations in fluid pressure in said straight air pipe and an opposing fluid pressure in a chamber normally open to said straight air pipe through a restricted communication, means operative upon a chosen increase in pressure in said straight air pipe to open another restricted communication between said chamber and straight air pipe, said abutment being operable upon an initial chosen rate of increase in straight air pipe pressure and upon a faster chosen rate of increase in pressure in said straight air pipe subsequent to operation of said means, to render said train control means ineffective, said rates exceeding the rates of increase in pressure in said chamber, said restricted communications having such flow capacity with respect to the volume of said chamber as to render said suppression means non-operable to maintain said train control means ineffective upon an increase in straight air pipe pressure at rates less than said chosen rates. I

20. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to eflect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied to effect an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said straight air pipe, and suppression means for rendering said train control means either efiective or ineffective upon a change in track signals, said suppression means including a movable abutment subject to variations in fluid pressure in said straight air pipe and an opposing fluid'pressure 'in a chamber normally open to said straight air pipe through a restricted communication, means operative upon a chosen increase in pressure in said straight air pipe to open another restricted communication between said chamber and straight air pipe, said abutment being operable upon an initial chosen rate of increase in straight air pipe pressure and upon a faster chosen rate of increase in pressure in said straight air pipe subsequent to o eration of said means, to render said train control means ineffective, the flow capacity of the first named restricted communication being so related to the volumeof said chamber that after said initial increase in straight air pipe pressure at the chosen rate a sufficient difierential between the pressures in said straight air pipe and i chamber will be provided on said abutment to hold said suppression means in condition to rende'r said train control means ineffective for a chosen interval of time without further supply of fluid under pressure to said straight air pipe, a further increase in straight air pipe pressure being then effective to maintain said suppression means in said condition, and means operative upon an increase in pressure in said straight air pipe to a chosen higher degree to vent fluid under pressure from said chamber for locking said suppression means by straight air pipe pressure in the condition for maintaining said train control means ineiiective.

21. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device for supplying fluid under pressure to said straight air pipe, and suppression means for rendering said train control means ineffective upon operation of said brake valve device prior to operation of said train control means, said suppression means comprising a pair of springs, movable abutment means having a normal position for rendering said train control means efiective and being movable therefrom upon a certain increase in said straight air pipe pressure against one of said springs to a temporary suppression position for rendering said train control means inefiective and against the: other of said springs upon a further increase in straight air pipe pressure to a permanent suppression position for maintaining said train control means ineffective, and timing means conditioned uponsaid certain increase in straight air pipe pressure to maintain said suppression means in said temporary suppression position for a chosen interval of time.

22. In a :fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device for supplying fluid under pressure to said straight air pipe, and suppression means for rendering said train control means inefiective upon operation or said brake valve device prior to operation of said train control means, said suppression means comprising a pair of springs, movable abutment means having a normal position for rendering said train control means effective and being movable therefrom upon a certain increase in said straight air pipe pressure against one of said springs to a temporary suppression position for rendering said train control means ineifective and against the other of said springs upon a further increase in straight air pipe pressure to a permanent suppression position for maintaining said train control means ineffective, timing means conditioned in said temporary suppression position to render the said one spring effective to move said abutment means back to said normal position after a chosen interval of time, and means operative upon movement of said abutment means to'said permanent suppression position prior to termination of said interval of time to lock said abutment means therein.

23. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for effecting an application of brakes, an engineers brake valve device for supplying fluid under pressure to said straight air pipe, valve means for rendering said train control means ineffective upon operation of said brake va ve device prior to operation or" said train control means, said valve means having a normal position for rendering said train control means effective and being movable therefrom to a temporary suppression position and further to a permanent suppression position for rendering said train control means ineffective,

a chamber, said valv means in said temporary suppression position opening a communication for charging said chamber with iiuid under pressure at a restricted rate and in said permanent suppression position venting fluid under pressure from said chamber, movable abutment means for moving said valve means to its different position and subject to the pressure of fluid in said straight air pipe and the opposing pressure of fluid in said chamber, a spring for opposing movement of said abutment means from said normal position to temporary suppression position, another spring for opposing movement of said abutment means from said temporary suppression position to said permanent suppression position, an increase in straight air pipe pressure at a rate sufiiciently exceeding the rate of increase in pressure in said chamber being adapted to operate said abutment means to move said valve means to said permanent suppression position, the first named spring being operative to actuate said abutment means to mcvesaid valve means to said normal position upon aslower rate of increase in straight air pipe pressure.

24. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to Whichfluid under pressure is adapted to 'be supplied for effecting an application of brakes, an engineers brake valve device for supplying fluid under pressure tosaid straight air pipe, valve means for rendering said train control means inefiective upon operation of said brake valve device prior to operationof said train control means, said valve means having a normal position for rendering said train control means effective and being movable therefrom to a temporary suppression position and further to a permanent suppression position for rendering said train control means ineffective, a chamber, a movable abutment for moving said valve means to its diflerent positions and subject to pressure of fluid in said straight air pipe and the opposing pressure of fluid in said chamber, a spring for opposing operation of said abutment to move said valve means from said normal position to said temporary suppression position, a second spring for opposing operation of the abutment to move said valve means from said temporary suppression position to said permanent suppression position, said valve means being operative during an initial stage of increase in pressure in said straight air pipe to supply fluid under pressure to said chamber at a restricted rate, and means operative during a subsequent stage of increase in straight air pipe pressure to increase the rate at which fluid under pressure is supplied to said chamber, said abutment being movable against said springs upon an increase in straight air pipe pressure at a rate sufliciently exceeding the rates of increase in pressure in said chamber to move said valve means to.said temporary suppression position and then to said permanent suppression position, said valve means in said permanent suppression position venting said chamber for locking said abutment and valve means in said permanent suppression position by straight air pipe pressure.

25. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to efiect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for eiTecting an application of brakes, an engineers brake valve device for supplying fluid under pressure to said straight air pipe, valve means for rendering said train control means inefiective upon operation of said brake valve device prior to operation of said train control means, said valve means having a normal position for rendering said train control means effective and being movable therefrom to a temporary suppression position and further to a permanent suppression position for rendering said train control means ineffective, a chamber, a movable abutment for moving said valve means to its difierent positions and subject to pressure of fluid in said straight air pipe and the opposing pressure of fluid in said chamber, a spring for opposing operation of said abutment to move said valve means from said normal position to said temporary suppression position, a second spring for opposing operation of the abutment to move said valve means from said temporary suppression position to said permanent suppression position, said valve means being operative during an initial stage of increase in pressure in straight air pipe to supply fluid under pressure to said chamber at a restricted rate, means operative during a subsequent stage of increase in straight air pipe pressure to increase the rate at which fluid under pressure is supplied to said chamber, said abutment being movable against the first named spring to said temporary suppression position and being maintained therein upon an increase in straight air pipe pressure at a rate sufiiciently exceeding the rates of increase in pressure in said chamber, and a valve device operative upon an increase in straight air pipe pressure to a desired relatively high degree for venting fluid under pressure from said chamher to thereby render said abutment operative to move said valve means to said permanent suppression position, said valve means in said permanent suppression position also venting said chamber. r

26. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a straight air pipe to which fluid under pressure is adapted to be supplied for eflecting an application of brakes, an engineers brake valve device for supplying fluid under pressure to said straight air pipe, and suppression means adapted to be operated by fluid under pressure supplied to said straight air pipe by operation of said brake valve device prior to operation of train control means to prevent operationof said train control upon a change in track signals, said suppression means comprising a movable abutment having at one side a chamber open to said straight air pipe, a valve having a normal position for rendering said train control means inelfective upon a change in track signals, saidvalve being movable by said abutment upon an increase in straight air pipe pressure in said chamber from said normal position to a temporary suppression position for rendering said train control means inefiective, a volume in which a predetermined variation in pressure in a certain interval of time is operative to render said train control means effective, said valve in said temporary suppression position being operative to eflect said variation in pressure in said chamber, a further increase in pressure insaid straight air pipe on said abutment prior to termination of saidinterval of time being operative to move said valve to a permanent suppression position for maintaining said train control means ineffective, and said train control means being operative upon response to a change in track signals to supply fluid to counteract straight air pipe pressure in said chamber acting on said movable abutment to render said abutment non-operable by fluid pressure supplied to said chamber.

27. In a fluid pressure brake, in combination, a pipe to which fluid under pressure is adapted to be supplied to effect an application of the brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said pipe, train control means operative automatically upon a change in track signals to effect an application of brakes, and suppression means operative upon said operation of said brake valve device prior to response of said train control means to a change in track signals to render said train control means ineflective, said suppression means comprising a movable abutment subject to variations in pressure in said pipe and being movable upon a certain increase in pressure in said pipe to a temporary suppression position, timing means conditioned to operate in said temporary suppression position to render said train control means ineffective for a certain interval of time, means operative at the expiration of said interval of time to render said train control means effective, said abutment being movable by a further increase in pressure in said pipe prior to the expiration of said interval of time to a permanent suppression position for maintaining said train control means inefiective.

28. In a fluid pressure brake, in combination, train control means operative automatically upon a change in track signals to effect an application of brakes, a pipe to which fluid under pressure is adapted to be supplied to effect an application of brakes, an engineers brake valve device operative to effect a supply of fluid under pressure to said pipe, and suppression means operative upon .said operation of said brake valve device prior to response of said train control meansto achange intrack signals to render said train control means ineffective, said suppression means comprising .movable abutment means, a valve movableby said abutment means andhaving anormal position forrendering said train control means effective andbeing movable therefrom to a temporary suppression position andfurther to a permanent suppression position for rendering said train control means inefiective, a spring for opposing movement of said valve .tov said temporary suppression position, another spring for opposing movement of said valve to said permanent suppression position, said abutment means being subject to pressure in said pipe and to the opposing pressure of fluid in a chamber, said valve in said normal and temporary suppression: positions establishing a restricted communication between said pipe and said chamber whereby an increase in pressure in said pipe at a rate sufliciently exceeding-the increase in pressure in said chamber will actuate said abutment means to move said valve to said temporary suppression position against the first named spring and whereby upon an increase in :pressure in said pipe to a predetermined degree, said abutment means and valve will remain in said temporary suppression position for a chosen interval of time without further increase in pressure in said pipe, valve means operative upon a further increase in pressure in said pipe to increase the rate at which fluid is supplied from said pipe to said chamber -for requiring 'a faster-rate of increase in pressure in said pipe to maintain said valve in said temporary suppression position, and other valve means operative upon an increase in pressure insaid pipe to a still higher degree for venting fluid under pressure from said chamber to render the pressure in said pipe operative to actuate said abutment means to move said valve to said permanent suppression position, said train control means being operative in effecting an application of brakes to supply fluid under all) pressure to said chamber to render said sup pression means non-Operable.

2,9. In a fluid pressure brake, in combination, train control means operative automatical y upon a change in track signals to eiiect an ap-- plication of brakes, a pipe to which fluid under pressure is adapted to be supplied to effect an application of brakes, anengineers brake valve device operative to effect a supply of fluid under pressure to said pipe, and suppression means operative upon said operation of said brake valve device prior to response of said train control means to a change in track signals to render said train control means ineffective, said suppression means comprising .a valve operative by fluid under pressure torender said train control means ineffective and operative when the pressure of such fluid is reduced to a low degree to render said train control means efiective, a pair of springs, a chamber, valve means, and movable abutment means subject to pressure of fluid in said pipe and operative upon a chosen initial increase in pressure in said pipe to move said valve means from a normal position to a temporary suppression position against the pressure of one of said springs and upon alfurther increase in pressure in saidpipeto a permanent suppression positicn against the other spring, said valve means in said normal position connecting said chamber to said pipe to provide for charging of said chamber with fluid under pressure from said pipe and in said temporary suppression position connecting said chamber to said valve and to a restricted atmospheric vent whereby the pressure in said chamber is adapted to gradually reduce and when reduced to a chosen low degree to hold said valve in the position to render said train control means ineffective, said valve means in said permanent suppression position being operative to supply fluid under pressure from said pipe to said valve to maintain said train control means ineffective, said train control -means being operative in effecting an application of brakes tosupplyfluid under pressure to act on said abutmentmeans for rendering same non-operable by fluid under pressure from said pipe.

ERIK G. ERSON. 

